Your search keyword '"Single molecule"' showing total 3,052 results

1. Exploring water−macromolecule interactions at the single-molecule level: A comprehensive review

Author

Shan, Yixuan, Bao, Yu, and Cui, Shuxun

Published

2024

2. Single-molecule toxicogenomics: Optical genome mapping of DNA-damage in nanochannel arrays

Author

Detinis Zur, Tahir, Margalit, Sapir, Jeffet, Jonathan, Grunwald, Assaf, Fishman, Sivan, Tulpová, Zuzana, Michaeli, Yael, Deek, Jasline, and Ebenstein, Yuval

Published

2025

3. AGEing of collagen: The effects of glycation on collagen’s stability, mechanics and assembly

Author

Sloseris, Daniel and Forde, Nancy R.

Published

2025

4. A review on nanopores based protein sensing in complex analyte

Author

Das, Naren, Chakraborty, Bhaswati, and RoyChaudhuri, Chirasree

Published

2022

5. Effect of chemical modification on the distribution of electrophoretic mobilities of individual molecules of E. coli β-galactosidase.

Author

Riehl, Brynne K., Klassen, Allyster B.T., Abas, Sumaiya, Pathak, Winner, and Craig, Douglas B.

Subjects

*SINGLE molecules, *ESCHERICHIA coli, *MOLECULAR shapes, *PROTEIN models, *MOLECULES

Abstract

Escherichia coli β-galactosidase was labelled with 1 mmol/L fluorescein 5-carbamoylmethylthiopropanoic N-hydroxysuccinimidyl ester for 1 and 3 min. The samples were separated by capillary electrophoresis and peak areas compared to that of labelled BSA for the purpose of quantification of the concentration of attached label. Enzyme concentration in the samples was determined by single molecule counting. The average number of labels attached to each molecule of enzyme was found to be 3.1 and 4.5 when labelled for 1 and 3 min, respectively. The distribution of single enzyme molecule electrophoretic mobilities for the unlabelled enzyme and that labelled for 1 and 3 min were measured using capillary electrophoresis. The average mobilities were found determined to be −(1.99 ± 0.13) × 10–8 m2 V−1 s−1 (N = 39), −(2.16 ± 0.19) × 10–8 m2 V−1 s−1 (N = 46), and –(2.18 ± 0.21) × 10–8 m2 V−1 s−1 (N = 39), respectively. A protein electrophoresis model was applied and predicted that the differences in average mobilities could be explained through relatively minor changes in overall charge, Stokes radius, and shape. This difference was similar to the range in mobilities observed in the unlabelled protein. This is consistent with the electrophoretic heterogeneity of the unmodified enzyme being caused by relatively small differences in charge, size, and shape of the individual molecules in the population. [ABSTRACT FROM AUTHOR]

Published

2025

6. RNA helicases DDX3X and DDX3Y form nanometer-scale RNA-protein clusters that support catalytic activity.

Author

Yanas, Amber, Shweta, Him, Owens, Michael C., Liu, Kathy Fange, and Goldman, Yale E.

Subjects

*SINGLE molecules, *STRESS granules, *SEX chromosomes, *CATALYTIC activity, *HELICASES, *DNA helicases, *RNA metabolism

Abstract

DEAD-box helicases, crucial for many aspects of RNA metabolism, often contain intrinsically disordered regions (IDRs) whose functions remain unclear. Using multiparameter confocal microscopy, we reveal that sex chromosome-encoded homologous RNA helicases, DDX3X and DDX3Y, form nanometer-scale RNA-protein clusters (RPCs) that foster their catalytic activities in vitro and in cells. The IDRs are critical for the formation of these RPCs. A thorough analysis of the catalytic cycle of DDX3X and DDX3Y by ensemble biochemistry and single-molecule photon bursts in the confocal microscope showed that RNA release is a major step that differentiates the unwinding activities of DDX3X and DDX3Y. The N-terminal IDRs of DDX3X and DDX3Y are both the drivers of RPC formation and the major differentiators of their enzymatic activities. Our findings provide new insights that the nanoscale helicase RPCs may be the normal state of these helicases under non-stressed conditions that promote their RNA unwinding and might act as nucleation points for stress granule formation. This mechanism may apply broadly among other members of the DEAD-box helicase family. [Display omitted] • DDX3X and DDX3Y form nanometer-scale protein-RNA clusters in vitro and in cells • Sequence differences in IDRs drive differences in cluster formation and catalysis • Single-strand RNA release rates underlie catalytic differences between DDX3X/DDX3Y • DDX3X mutants show a relationship between cluster size and RNA unwinding activity Yanas et al. report that RNA helicases DDX3X and DDX3X form nanometer-scale RNA-protein clusters (RPCs) both in vitro and in cells. Differences in RPC size and catalytic activity between DDX3X and DDX3Y are determined by sequence differences in the two homologs' IDRs. Using DDX3X mutants, the authors find that RPC size correlates with helicase activity. [ABSTRACT FROM AUTHOR]

Published

2024

7. Single-Molecule Analysis of Alkaline Phosphatase.

Author

Craig, Douglas B.

Subjects

*SINGLE molecules, *ALKALINE phosphatase, *ACTIVATION energy, *MOLECULES, *MIXTURES

Abstract

Chemical studies usually consist of measurements made on large ensembles of molecules with data representing average values for the population. It has been shown that individual molecules of a given enzyme have different properties. Large-scale averaging has in the past masked these differences. Alkaline phosphatase has been used as a model to study this enzyme heterogeneity. The catalytic rates of the individual molecules have been found to differ by over 10-fold, and the activation energy of catalysis by more than two-fold. Differences in properties indicate that differences in structure must exist between the molecules. For alkaline phosphatase, the structural differences have been suggested to be differences in glycosylation, differences due to partial proteolysis, and due to some molecules containing mixtures of active and inactive subunits. The determination of the distribution of activities of populations of this enzyme within a sample has also been shown to be a useful tool in diagnostics. This review discusses the advent of single-molecule enzymology and summarizes its use in the study of alkaline phosphatase using capillary electrophoresis, microscopic well assays, and single-molecule tracking. [ABSTRACT FROM AUTHOR]

Published

2024

8. Nanopipettes as a Potential Diagnostic Tool for Selective Nanopore Detection of Biomolecules.

Author

Kuanaeva, Regina M., Vaneev, Alexander N., Gorelkin, Petr V., and Erofeev, Alexander S.

Subjects

SINGLE molecules, MOLECULAR diagnosis, NANOTECHNOLOGY, INDIVIDUALIZED medicine, BIOMOLECULES

Abstract

Nanopipettes, as a class of solid-state nanopores, have evolved into universal tools in biomedicine for the detection of biomarkers and different biological analytes. Nanopipette-based methods combine high sensitivity, selectivity, single-molecule resolution, and multifunctionality. The features have significantly expanded interest in their applications for the biomolecular detection, imaging, and molecular diagnostics of real samples. Moreover, the ease of manufacturing nanopipettes, coupled with their compatibility with fluorescence and electrochemical methods, makes them ideal for portable point-of-care diagnostic devices. This review summarized the latest progress in nanopipette-based nanopore technology for the detection of biomarkers, DNA, RNA, proteins, and peptides, in particular β-amyloid or α-synuclein, emphasizing the impact of technology on molecular diagnostics. By addressing key challenges in single-molecule detection and expanding applications in diverse biological areas, nanopipettes are poised to play a transformative role in the future of personalized medicine. [ABSTRACT FROM AUTHOR]

Published

2024

9. Single-Molecule Tracking in Live Cell without Immobilization or without Hydrodynamic Flow by Simulations: Thermodynamic Jitter

Author

Gerd Baumann and Zeno Földes-Papp

Subjects

individual molecule tracking, individual molecule, single molecule, diffusion, thermodynamic jitter, live cell, Biology (General), QH301-705.5

Abstract

Experiments to measure a single molecule/particle, i.e., an individual molecule/particle, at room temperature or under physiological conditions without immobilization—for example, on a surface or without significant hydrodynamic flow—have so far failed. This failure has given impetus to the underlying theory of Brownian molecular motion towards its stochastics due to diffusion. Quantifying the thermodynamic jitter of molecules/particles inspires many and forms the theoretical basis of single-molecule/single-particle biophysics and biochemistry. For the first time, our simulation results for a live cell (cytoplasm) show that the tracks of individual single molecules are localized in Brownian motion, while there is fanning out in fractal diffusion (anomalous diffusion).

Published

2024

10. Excitation Wavelength Dependent Fluorescence and Phosphorescence from Organic Ionic Crystalline Powder.

Author

Gong, Qi, Dai, Xianyin, Yuan, Chunhao, Li, Jinwei, Zhang, Yipeng, Zhang, Jiesen, and Ge, Yanqing

Subjects

*SALT crystals, *POLAR effects (Chemistry), *IONIC bonds, *LUMINESCENCE, *INTERMOLECULAR interactions, *PHOSPHORESCENCE

Abstract

A new type of material, organic salts in the crystal and crystalline powder state, with both excitation wavelength dependent (Ex‐De) fluorescence and Ex‐De phosphorescence under ambient conditions have been reported. The single component triphenylsulfonium chloride displays tunable fluorescent colors ranging from light purple to sky blue and tunable afterglow colors varying from green to yellowish green, to yellow (lifetimes: 57, 141, 66 ms, afterglow lasting for 2.1, 2.0, 2.3 s). The relationship between the structure and luminescence performance of 17 sulfonium salt derivatives confirms the pivotal roles of both the anions and the electronic and steric effect of substituent factors for luminescence. Single‐crystal analysis reveals that unique ionic bonding and intermolecular interaction can promote an ordered arrangement of organic salts in a crystal state, which then can facilitate molecular aggregation for phosphorescence generation. Theoretical calculations have also confirmed this viewpoint. More importantly, these sulfonium salt derivatives can be used for advanced multimodal anti‐counterfeiting and mitochondrial imaging, respectively. This study has not only expanded the scope of Ex‐De materials but also extended their applications. [ABSTRACT FROM AUTHOR]

Published

2024

11. Secondary Nucleation of Aβ Revealed by Single‐Molecule and Computational Approaches.

Author

Meyer, Nathan, Arroyo, Nicolas, Roustan, Lois, Janot, Jean‐Marc, Charles‐Achille, Saly, Torrent, Joan, Picaud, Fabien, and Balme, Sébastien

Subjects

*ALZHEIMER'S disease, *FLUORESCENCE spectroscopy, *SINGLE molecules, *MOLECULAR dynamics, *AMYLOID

Abstract

Understanding the mechanisms underlying amyloid‐β (Aβ) aggregation is pivotal in the context of Alzheimer's disease. This study aims to elucidate the secondary nucleation process of Aβ42 peptides by combining experimental and computational methods. Using a newly developed nanopipette‐based amyloid seeding and translocation assay, confocal fluorescence spectroscopy, and molecular dynamics simulations, the influence of the seed properties on Aβ aggregation is investigated. Both fragmented and unfragmented seeds played distinct roles in the formation of oligomers, with fragmented seeds facilitating the formation of larger aggregates early in the incubation phase. The results show that secondary nucleation leads to the formation of oligomers of various sizes and structures as well as larger fibrils structured in β‐sheets. From these findings a mechanism of secondary nucleation involving two types of aggregate populations, one released and one growing on the mother fiber is proposed. [ABSTRACT FROM AUTHOR]

Published

2024

12. Single-Molecule Tracking in Live Cell without Immobilization or without Hydrodynamic Flow by Simulations: Thermodynamic Jitter †.

Author

Baumann, Gerd and Földes-Papp, Zeno

Subjects

HYDRODYNAMICS, BROWNIAN motion, COMPUTER simulation, RANDOM walks, BIOPHYSICS

Abstract

Experiments to measure a single molecule/particle, i.e., an individual molecule/particle, at room temperature or under physiological conditions without immobilization—for example, on a surface or without significant hydrodynamic flow—have so far failed. This failure has given impetus to the underlying theory of Brownian molecular motion towards its stochastics due to diffusion. Quantifying the thermodynamic jitter of molecules/particles inspires many and forms the theoretical basis of single-molecule/single-particle biophysics and biochemistry. For the first time, our simulation results for a live cell (cytoplasm) show that the tracks of individual single molecules are localized in Brownian motion, while there is fanning out in fractal diffusion (anomalous diffusion). [ABSTRACT FROM AUTHOR]

Published

2024

13. 实现生物单分子成像的液相扫描电镜新技术.

Author

王 丽, 曹聪慧, 宋 晶, 崔依然, 李长硕, 翟亚迪, 李劲涛, 吉 元, and 韩晓东

Subjects

TRIPLE-negative breast cancer, MEMBRANE proteins, SINGLE molecules, SCANNING electron microscopy, ATOMIC number

Abstract

Copyright of Journal of Beijing University of Technology is the property of Journal of Beijing University of Technology, Editorial Department and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

14. Exploring water−macromolecule interactions at the single-molecule level: A comprehensive review

Author

Yixuan Shan, Yu Bao, and Shuxun Cui

Subjects

Single molecule, AFM, Water, Macromolecules, Interactions, Chemistry, QD1-999

Abstract

Water is ubiquitous and indispensable on the Earth. Its importance has long been recognized on a macroscopic scale. However, it took a long time to comprehend the impact of water molecules on the microscopic level. According to the hydrophilicity of matter, the impact of water can be divided into two categories: 1) intermolecular hydrogen bonds (H-bonds) and 2) hydrophobic interactions. In recent years, atomic force microscopy (AFM)-based single-molecule force spectroscopy (SMFS) has been used to investigate the effect of water on the single-chain properties of macromolecules. Herein, we summarize recent advances in the AFM-SMFS study on the impact of water on some kinds of synthetic polymers, biomacromolecules, and molecules containing supramolecular interactions from the two aspects of H-bonds and hydrophobic interactions. It is expected that a deeper understanding of the interactions between water molecules and macromolecules will enable the design of polymer materials with specific functionalities and properties in a bottom-up way.

Published

2024

15. Sequential replacement of PSD95 subunits in postsynaptic supercomplexes is slowest in the cortex

Author

Katie Morris, Edita Bulovaite, Takeshi Kaizuka, Sebastian Schnorrenberg, Candace T Adams, Noboru Komiyama, Lorena Mendive-Tapia, Seth GN Grant, and Mathew H Horrocks

Subjects

synapse, single molecule, PSD95, synaptome, Medicine, Science, Biology (General), QH301-705.5

Abstract

The concept that dimeric protein complexes in synapses can sequentially replace their subunits has been a cornerstone of Francis Crick’s 1984 hypothesis, explaining how long-term memories could be maintained in the face of short protein lifetimes. However, it is unknown whether the subunits of protein complexes that mediate memory are sequentially replaced in the brain and if this process is linked to protein lifetime. We address these issues by focusing on supercomplexes assembled by the abundant postsynaptic scaffolding protein PSD95, which plays a crucial role in memory. We used single-molecule detection, super-resolution microscopy and MINFLUX to probe the molecular composition of PSD95 supercomplexes in mice carrying genetically encoded HaloTags, eGFP, and mEoS2. We found a population of PSD95-containing supercomplexes comprised of two copies of PSD95, with a dominant 12.7 nm separation. Time-stamping of PSD95 subunits in vivo revealed that each PSD95 subunit was sequentially replaced over days and weeks. Comparison of brain regions showed subunit replacement was slowest in the cortex, where PSD95 protein lifetime is longest. Our findings reveal that protein supercomplexes within the postsynaptic density can be maintained by gradual replacement of individual subunits providing a mechanism for stable maintenance of their organization. Moreover, we extend Crick’s model by suggesting that synapses with slow subunit replacement of protein supercomplexes and long-protein lifetimes are specialized for long-term memory storage and that these synapses are highly enriched in superficial layers of the cortex where long-term memories are stored.

Published

2024

16. A single molecule spectroscopy approach towards understanding the structure of catalytically active sites

Author

Anetts, Simon Roy and Schaub, Renald

Subjects

STM, STM-IETS, Single molecule, Single molecule vibrational spectroscopy, Surface science, Chemistry, Physical chemistry, Cu(110), Carbon monoxide

Abstract

The work presented in this thesis has been performed with the aim of increasing our understanding of relationships between the structure of an adsorption site and the extent of adsorbate activation, a key step in catalytic processes. Unravelling such structure-performance relationships is often hindered by the complex structures displayed by heterogeneous catalysts; they can be multiphasic and are typically dynamic in nature with respect to structure, composition and local electronic environment. A reactive surface can be comprised of many step edges, kinks and defect sites, but only a small portion of this rich structural diversity may be responsible for catalytic activity. The challenges associated with identifying the structure of active sites can be simplified through the interrogation of single crystal surfaces, for which structural complexity is greatly reduced. By using a low temperature, ultra-high vacuum scanning tunnelling microscope (LT-UHV-STM), individual surface sites of interest can be identified and investigated on an atomic scale. The application of STM-inelastic electron tunnelling spectroscopy (STM-IETS) and scanning tunnelling spectroscopy (STS), allows the bond strength, and therefore the extent of adsorbate activation to be studied at surface sites of differing geometric and electronic structure. The work described in this thesis has focussed on the development of STM-IETS and STS to investigate the interaction of carbon monoxide (CO) with Cu-based surfaces. CO is an ideal probe molecule given the sensitivity of its vibrational frequency to local structure and its use as a C₁ building block in chemical processes. On Cu(110), adsorbed CO forms one-dimensional structures where the nearest neighbour sites are occupied in the [001] direction. The vibrational frequency of adsorbed CO is highly dependent on the CO coverage. A CO molecule with one of its nearest neighbour sites occupied by CO (a CO adsorption dimer) exhibits an increased C-O bond strength (higher frequency) relative to a terrace monomer. This is assigned to dipole-dipole coupling effects between neighbouring molecules. Conversely, the CO bond is weakened compared to a terrace monomer, when two nearest neighbour sites of the adsorbate are also occupied (a CO adsorption trimer). This is attributed to chemical effects that cause a broadening of the CO 2π* orbital and its increased occupancy. Further investigations have explored the effects of the structure of adsorption site on the CO bond strength. CO adsorbed at the lower [001] aligned Cu(110) step edge sites, exhibits lower CO stretching frequency when compared to CO adsorbed at the upper edge sites. This can again be attributed to changes in the occupancy of the antibonding 2π* orbital that is driven in this case by a substantial difference in electron density associated with these adsorption sites. The aforementioned studies have been extended to investigations of Co, a metal upon which CO activation is of great interest. Given the complexities of preparing Co single crystals, a model surface was formed by depositing Co on Cu(110). When deposition is performed in the presence of CO, a novel CoCu(110) alloy is formed in which two-atom wide Co structures aligned in the [001] direction are embedded in the first layer of the Cu(110) surface. When CO is adsorbed between the linear arrangements of Co atoms, there is a far greater activation of the CO bond relative to the Cu(110) surface. The results demonstrate the broad application of the STM-IETS approach to studying complex surfaces and the ability to provide deeper insights into data that is traditionally generated using techniques that provide a macroscopic picture of a surface.

Published

2023

17. Electrochemiluminescence Microscopy.

Author

Knežević, Sara, Han, Dongni, Liu, Baohong, Jiang, Dechen, and Sojic, Neso

Subjects

*MATERIALS science, *MICROSCOPY, *CHEMICAL reactions, *SINGLE molecules, *CHEMILUMINESCENCE, *PHOTONS, *SCANNING electrochemical microscopy, *ELECTROCHEMILUMINESCENCE

Abstract

Electrochemiluminescence (ECL) is rapidly evolving from an analytical method into an optical microscopy. The orthogonality of the electrochemical trigger and the optical readout distinguishes it from classic microscopy and electrochemical techniques, owing to its near‐zero background, remarkable sensitivity, and absence of photobleaching and phototoxicity. In this minireview, we summarize the recent advances in ECL imaging technology, emphasizing original configurations which enable the imaging of biological entities and the improvement of the analytical properties by increasing the complexity and multiplexing of bioassays. Additionally, mapping the (electro)chemical reactivity in space provides valuable information on nanomaterials and facilitates deciphering ECL mechanisms for improving their performances in diagnostics and (electro)catalysis. Finally, we highlight the recent achievements in imaging at the ultimate limits of single molecules, single photons or single chemical reactions, and the current challenges to translate the ECL imaging advances to other fields such as material science, catalysis and biology. [ABSTRACT FROM AUTHOR]

Published

2024

18. Recruitment of HAB1 and SnRK2.2 by C2‐domain protein CAR1 in plasma membrane ABA signaling.

Author

Guo, Ai‐Yu, Wu, Wen‐Qiang, Bai, Di, Li, Yan, Xie, Jie, Guo, Siyi, and Song, Chun‐Peng

Subjects

*CELL membranes, *BLOOD proteins, *ABSCISIC acid, *CELLULAR signal transduction, *PROTEIN kinases, *GENE families

Abstract

SUMMARY: Plasma membrane (PM)‐associated abscisic acid (ABA) signal transduction is an important component of ABA signaling. The C2‐domain ABA‐related (CAR) proteins have been reported to play a crucial role in recruiting ABA receptor PYR1/PYL/RCAR (PYLs) to the PM. However, the molecular details of the involvement of CAR proteins in membrane‐delimited ABA signal transduction remain unclear. For instance, where this response process takes place and whether any additional members besides PYL are taking part in this signaling process. Here, the GUS‐tagged materials for all Arabidopsis CAR members were used to comprehensively visualize the extensive expression patterns of the CAR family genes. Based on the representativeness of CAR1 in response to ABA, we determined to use it as a target to study the function of CAR proteins in PM‐associated ABA signaling. Single‐particle tracking showed that ABA affected the spatiotemporal dynamics of CAR1. The presence of ABA prolonged the dwell time of CAR1 on the membrane and showed faster lateral mobility. Surprisingly, we verified that CAR1 could directly recruit hypersensitive to ABA1 (HAB1) and SNF1‐related protein kinase 2.2 (SnRK2.2) to the PM at both the bulk and single‐molecule levels. Furthermore, PM localization of CAR1 was demonstrated to be related to membrane microdomains. Collectively, our study revealed that CARs recruited the three main components of ABA signaling to the PM to respond positively to ABA. This study deepens our understanding of ABA signal transduction. [ABSTRACT FROM AUTHOR]

Published

2024

19. Optical Tweezers to Study Viruses

Author

Arias-Gonzalez, J. Ricardo, Kundu, Tapas K., Series Editor, Harris, J. Robin, Advisory Editor, Holzenburg, Andreas, Advisory Editor, Korolchuk, Viktor, Advisory Editor, Bolanos-Garcia, Victor, Advisory Editor, Marles-Wright, Jon, Advisory Editor, and Mateu, Mauricio G., editor

Published

2024

20. Ångström-Resolved Tip-Enhanced Raman Spectroscopy

Author

Zhang, Yao, Dong, Zhen-Chao, Procházka, Marek, editor, Kneipp, Janina, editor, Zhao, Bing, editor, and Ozaki, Yukihiro, editor

Published

2024

21. Solid-State Nanopores for Biomolecular Analysis and Detection

Author

Stuber, Annina, Schlotter, Tilman, Hengsteler, Julian, Nakatsuka, Nako, Scheper, Thomas, Editorial Board Member, Belkin, Shimshon, Editorial Board Member, Bley, Thomas, Editorial Board Member, Bohlmann, Jörg, Editorial Board Member, Gu, Man Bock, Editorial Board Member, Hu, Wei Shou, Editorial Board Member, Mattiasson, Bo, Editorial Board Member, Olsson, Lisbeth, Editorial Board Member, Seitz, Harald, Editorial Board Member, Silva, Ana Catarina, Editorial Board Member, Ulber, Roland, Series Editor, Zeng, An-Ping, Editorial Board Member, Zhong, Jian-Jiang, Editorial Board Member, Zhou, Weichang, Editorial Board Member, Bühler, Katja, Editorial Board Member, Lavrentieva, Antonina, Editorial Board Member, Lisdat, Fred, editor, and Plumeré, Nicolas, editor

Published

2024

22. Secondary Nucleation of Aβ Revealed by Single‐Molecule and Computational Approaches

Author

Nathan Meyer, Nicolas Arroyo, Lois Roustan, Jean‐Marc Janot, Saly Charles‐Achille, Joan Torrent, Fabien Picaud, and Sébastien Balme

Subjects

amyloid, confocal fluorescence spectroscopy, nanopore, secondary nucleation, single molecule, Science

Abstract

Abstract Understanding the mechanisms underlying amyloid‐β (Aβ) aggregation is pivotal in the context of Alzheimer's disease. This study aims to elucidate the secondary nucleation process of Aβ42 peptides by combining experimental and computational methods. Using a newly developed nanopipette‐based amyloid seeding and translocation assay, confocal fluorescence spectroscopy, and molecular dynamics simulations, the influence of the seed properties on Aβ aggregation is investigated. Both fragmented and unfragmented seeds played distinct roles in the formation of oligomers, with fragmented seeds facilitating the formation of larger aggregates early in the incubation phase. The results show that secondary nucleation leads to the formation of oligomers of various sizes and structures as well as larger fibrils structured in β‐sheets. From these findings a mechanism of secondary nucleation involving two types of aggregate populations, one released and one growing on the mother fiber is proposed.

Published

2024

23. Optical Tweezers in Human Cancers

Author

ZHANG Baihong and YUE Hongyun

Subjects

cancer, optical tweezers, cell, single molecule, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Optical tweezers are a means to manipulate objects with light. Optical tweezers can obtain a nanometer space, piconewton force, and a millisecond resolution; thus, they are excellently suited for studying biological processes from the single-cell to the single-molecule level. Optical tweezers can screen and manipulate tumor cells, study single molecule, and monitor cancer treatments. Thus, optical tweezers will promote the progress of cancer research and treatments.

Published

2024

24. Dynamics and Stability Mechanism of Lactoferrin–EPA During Emulsification Process: Insights from Macroscopic and Molecular Perspectives

Author

Han Tao, Wei Ding, Meng-Jia Fang, Hao Qian, Wan-Hao Cai, and Hui-Li Wang

Subjects

lactoferrin, EPA, emulsion, dynamics, single molecule, Chemical technology, TP1-1185

Abstract

Although eicosapentaenoic acid (EPA) as a functional fatty acid has shown significant benefits for human health, its susceptibility to oxidation significantly limits its application. In this study, we developed a nanoemulsion of the lactoferrin (LTF)–EPA complex and conducted a thorough investigation of its macro- and molecular properties. By characterizing the emulsion with different LTF concentrations, we found that 1.0% LTF formed the most stable complex with EPA, which benefited the formation and stability of the emulsion against storage and freezing/thawing treatment. As the foundation block of the emulsion structure, the binding mechanism and the entire dynamic reaction process of the complex have been fully revealed through various molecular simulations and theoretical calculations. This study establishes a comprehensive picture of the LTF–EPA complex across multiple length scales, providing new insights for further applications and productions of its emulsion.

Published

2025

25. Nanopipettes as a Potential Diagnostic Tool for Selective Nanopore Detection of Biomolecules

Author

Regina M. Kuanaeva, Alexander N. Vaneev, Petr V. Gorelkin, and Alexander S. Erofeev

Subjects

nanopipette, nanopore, single molecule, molecular diagnostics, solid-state nanopore, Biotechnology, TP248.13-248.65

Abstract

Nanopipettes, as a class of solid-state nanopores, have evolved into universal tools in biomedicine for the detection of biomarkers and different biological analytes. Nanopipette-based methods combine high sensitivity, selectivity, single-molecule resolution, and multifunctionality. The features have significantly expanded interest in their applications for the biomolecular detection, imaging, and molecular diagnostics of real samples. Moreover, the ease of manufacturing nanopipettes, coupled with their compatibility with fluorescence and electrochemical methods, makes them ideal for portable point-of-care diagnostic devices. This review summarized the latest progress in nanopipette-based nanopore technology for the detection of biomarkers, DNA, RNA, proteins, and peptides, in particular β-amyloid or α-synuclein, emphasizing the impact of technology on molecular diagnostics. By addressing key challenges in single-molecule detection and expanding applications in diverse biological areas, nanopipettes are poised to play a transformative role in the future of personalized medicine.

Published

2024

26. 光镊在肿瘤研究中的应用.

Author

张百红 and 岳红云

Abstract

Optical tweezers are a means to manipulate objects with light. Optical tweezers can obtain a nanometer space, piconewton force, and a millisecond resolution; thus, they are excellently suited for studying biological processes from the single-cell to the single-molecule level. Optical tweezers can screen and manipulate tumor cells, study single molecule, and monitor cancer treatments. Thus, optical tweezers will promote the progress of cancer research and treatments. [ABSTRACT FROM AUTHOR]

Published

2024

27. Characterization of single synthetic polymers via magnetic tweezers.

Author

Xie, Jin, Zhou, Wenqiao, Mao, Xianwen, and Liu, Chunming

Subjects

POLYMERS, MAGNETIC tweezers, DNA, MAGNETS, MAGNETISM

Abstract

Due to the ability to perform the parallel measurement of multiple single chains and exert precise control over stretching force in the sub‐nanonewton regime, magnetic tweezers (MT) are a suitable tool to study the individual chain conformations and inherent behaviors of polymers. Herein, we examined the applications of MT in studying single synthetic polymers, distinct from previous reviews focusing on biological polymers such as DNAs. We first presented an overview of the technical aspects of MT, including the imaging setup, the algorithm of three‐dimensional single particle tracking, the configuration of magnets, the calibration and control of magnetic forces, the assembly of flow cells, and the polymer tethering methods. Then, we discussed selected examples highlighting the utilization of MT in studying the chain conformation, mechanical properties, ion and ligands effect, regime transition mechanism, and polymerization dynamics of single synthetic polymers. We envision that MT can serve as a powerful toolbox for delving into the structure–property correlations at the single chain level, which provides quantitative validations for building the theoretical models of synthetic polymers. In the end, we contemplated potential avenues and opportunities for future research in this domain. [ABSTRACT FROM AUTHOR]

Published

2024

28. Joint Efforts of Replicative Helicase and SSB Ensure Inherent Replicative Tolerance of G‐Quadruplex.

Author

Guo, Lijuan, Bao, Yanling, Zhao, Yilin, Ren, Zhiyun, Bi, Lulu, Zhang, Xia, Liu, Cong, Hou, Xi‐Miao, Wang, Michelle D., and Sun, Bo

Subjects

*DNA synthesis, *DNA structure, *DNA-binding proteins, *DNA replication, *SINGLE-stranded DNA, *REPLISOMES, *DNA polymerases, *DNA helicases

Abstract

G‐quadruplex (G4) is a four‐stranded noncanonical DNA structure that has long been recognized as a potential hindrance to DNA replication. However, how replisomes effectively deal with G4s to avoid replication failure is still obscure. Here, using single‐molecule and ensemble approaches, the consequence of the collision between bacteriophage T7 replisome and an intramolecular G4 located on either the leading or lagging strand is examined. It is found that the adjacent fork junctions induced by G4 formation incur the binding of T7 DNA polymerase (DNAP). In addition to G4, these inactive DNAPs present insuperable obstacles, impeding the progression of DNA synthesis. Nevertheless, T7 helicase can dismantle them and resolve lagging‐strand G4s, paving the way for the advancement of the replication fork. Moreover, with the assistance of the single‐stranded DNA binding protein (SSB) gp2.5, T7 helicase is also capable of maintaining a leading‐strand G4 structure in an unfolded state, allowing for a fraction of T7 DNAPs to synthesize through without collapse. These findings broaden the functional repertoire of a replicative helicase and underscore the inherent G4 tolerance of a replisome. [ABSTRACT FROM AUTHOR]

Published

2024

29. cAMP binding to closed pacemaker ion channels is cooperative.

Author

Kuschke, Stefan, Thon, Susanne, Sattler, Christian, Schwabe, Tina, Benndorf, Klaus, and Schmauder, Ralf

Subjects

*ION channels, *LIGAND binding (Biochemistry), *BINDING sites, *CELL membranes, *SINGLE molecules, *WAVEGUIDES

Abstract

The cooperative action of the subunits in oligomeric receptors enables fine-tuning of receptor activation, as demonstrated for the regulation of voltage-activated HCN pacemaker ion channels by relating cAMP binding to channel activation in ensemble signals. HCN channels generate electric rhythmicity in specialized brain neurons and cardiomyocytes. There is conflicting evidence on whether binding cooperativity does exist independent of channel activation or not, as recently reported for detergent-solubilized receptors positioned in zero-mode waveguides. Here, we show positive cooperativity in ligand binding to closed HCN2 channels in native cell membranes by following the binding of individual fluorescence-labeled cAMP molecules. Kinetic modeling reveals that the affinity of the still empty binding sites rises with increased degree of occupation and that the transition of the channel to a flip state is promoted accordingly. We conclude that ligand binding to the subunits in closed HCN2 channels not pre-activated by voltage is already cooperative. Hence, cooperativity is not causally linked to channel activation by voltage. Our analysis also shows that single-molecule binding measurements at equilibrium can quantify cooperativity in ligand binding to receptors in native membranes. [ABSTRACT FROM AUTHOR]

Published

2024

30. Mechanism of DNA Intercalation by Chloroquine Provides Insights into Toxicity.

Author

Joshi, Joha, McCauley, Micah J., Morse, Michael, Muccio, Michael R., Kanlong, Joseph G., Rocha, Márcio S., Rouzina, Ioulia, Musier-Forsyth, Karin, and Williams, Mark C.

Subjects

*ANTIMALARIALS, *INTERCALATION reactions, *DNA-ligand interactions, *ISOTHERMAL titration calorimetry, *POISONS, *CHLOROQUINE

Abstract

Chloroquine has been used as a potent antimalarial, anticancer drug, and prophylactic. While chloroquine is known to interact with DNA, the details of DNA–ligand interactions have remained unclear. Here we characterize chloroquine–double-stranded DNA binding with four complementary approaches, including optical tweezers, atomic force microscopy, duplex DNA melting measurements, and isothermal titration calorimetry. We show that chloroquine intercalates into double stranded DNA (dsDNA) with a KD ~ 200 µM, and this binding is entropically driven. We propose that chloroquine-induced dsDNA intercalation, which happens in the same concentration range as its observed toxic effects on cells, is responsible for the drug's cytotoxicity. [ABSTRACT FROM AUTHOR]

Published

2024

31. Joint Efforts of Replicative Helicase and SSB Ensure Inherent Replicative Tolerance of G‐Quadruplex

Author

Lijuan Guo, Yanling Bao, Yilin Zhao, Zhiyun Ren, Lulu Bi, Xia Zhang, Cong Liu, Xi‐Miao Hou, Michelle D. Wang, and Bo Sun

Subjects

DNA replication, G‐quadruplex, helicase, polymerase, single molecule, SSB, Science

Abstract

Abstract G‐quadruplex (G4) is a four‐stranded noncanonical DNA structure that has long been recognized as a potential hindrance to DNA replication. However, how replisomes effectively deal with G4s to avoid replication failure is still obscure. Here, using single‐molecule and ensemble approaches, the consequence of the collision between bacteriophage T7 replisome and an intramolecular G4 located on either the leading or lagging strand is examined. It is found that the adjacent fork junctions induced by G4 formation incur the binding of T7 DNA polymerase (DNAP). In addition to G4, these inactive DNAPs present insuperable obstacles, impeding the progression of DNA synthesis. Nevertheless, T7 helicase can dismantle them and resolve lagging‐strand G4s, paving the way for the advancement of the replication fork. Moreover, with the assistance of the single‐stranded DNA binding protein (SSB) gp2.5, T7 helicase is also capable of maintaining a leading‐strand G4 structure in an unfolded state, allowing for a fraction of T7 DNAPs to synthesize through without collapse. These findings broaden the functional repertoire of a replicative helicase and underscore the inherent G4 tolerance of a replisome.

Published

2024

32. Dynamic 1D search and processive nucleosome translocations by RSC and ISW2 chromatin remodelers

Author

Jee Min Kim, Claudia C Carcamo, Sina Jazani, Zepei Xie, Xinyu A Feng, Maryam Yamadi, Matthew Poyton, Katie L Holland, Jonathan B Grimm, Luke D Lavis, Taekjip Ha, and Carl Wu

Subjects

chromatin remodelers, RSC, ISW2, target search, single molecule, optical tweezers, Medicine, Science, Biology (General), QH301-705.5

Abstract

Eukaryotic gene expression is linked to chromatin structure and nucleosome positioning by ATP-dependent chromatin remodelers that establish and maintain nucleosome-depleted regions (NDRs) near transcription start sites. Conserved yeast RSC and ISW2 remodelers exert antagonistic effects on nucleosomes flanking NDRs, but the temporal dynamics of remodeler search, engagement, and directional nucleosome mobilization for promoter accessibility are unknown. Using optical tweezers and two-color single-particle imaging, we investigated the Brownian diffusion of RSC and ISW2 on free DNA and sparse nucleosome arrays. RSC and ISW2 rapidly scan DNA by one-dimensional hopping and sliding, respectively, with dynamic collisions between remodelers followed by recoil or apparent co-diffusion. Static nucleosomes block remodeler diffusion resulting in remodeler recoil or sequestration. Remarkably, both RSC and ISW2 use ATP hydrolysis to translocate mono-nucleosomes processively at ~30 bp/s on extended linear DNA under tension. Processivity and opposing push–pull directionalities of nucleosome translocation shown by RSC and ISW2 shape the distinctive landscape of promoter chromatin.

Published

2024

33. Single-Molecule X-ray Scattering Used to Visualize the Conformation Distribution of Biological Molecules via Single-Object Scattering Sampling.

Author

Lee, Seonggon, Ki, Hosung, Lee, Sang Jin, and Ihee, Hyotcherl

Subjects

*BIOMOLECULES, *X-ray scattering, *BIOMACROMOLECULES, *MOLECULAR structure, *GOLD nanoparticles, *ULTRASHORT laser pulses

Abstract

Biological macromolecules, the fundamental building blocks of life, exhibit dynamic structures in their natural environment. Traditional structure determination techniques often oversimplify these multifarious conformational spectra by capturing only ensemble- and time-averaged molecular structures. Addressing this gap, in this work, we extend the application of the single-object scattering sampling (SOSS) method to diverse biological molecules, including RNAs and proteins. Our approach, referred to as "Bio-SOSS", leverages ultrashort X-ray pulses to capture instantaneous structures. In Bio-SOSS, we employ two gold nanoparticles (AuNPs) as labels, which provide strong contrast in the X-ray scattering signal, to ensure precise distance determinations between labeled sites. We generated hypothetical Bio-SOSS images for RNAs, proteins, and an RNA–protein complex, each labeled with two AuNPs at specified positions. Subsequently, to validate the accuracy of Bio-SOSS, we extracted distances between these nanoparticle labels from the images and compared them with the actual values used to generate the Bio-SOSS images. Specifically, for a representative RNA (1KXK), the standard deviation in distance discrepancies between molecular dynamics snapshots and Bio-SOSS retrievals was found to be optimally around 0.2 Å, typically within 1 Å under practical experimental conditions at state-of-the-art X-ray free-electron laser facilities. Furthermore, we conducted an in-depth analysis of how various experimental factors, such as AuNP size, X-ray properties, and detector geometry, influence the accuracy of Bio-SOSS. This comprehensive investigation highlights the practicality and potential of Bio-SOSS in accurately capturing the diverse conformation spectrum of biological macromolecules, paving the way for deeper insights into their dynamic natures. [ABSTRACT FROM AUTHOR]

Published

2023

34. Symmetry and Rigidity for Boosting Erbium‐Based Molecular Light‐Upconversion in Solution.

Author

Naseri, Soroush, Taarit, Inès, Bolvin, Hélène, Bünzli, Jean‐Claude, Fürstenberg, Alexandre, Guénée, Laure, Le‐Hoang, Giau, Mirzakhani, Mohsen, Nozary, Homayoun, Rosspeintner, Arnulf, and Piguet, Claude

Subjects

*PHOTON upconversion, *SYMMETRY, *OPTICS

Abstract

Previously limited to highly symmetrical homoleptic triple‐helical complexes [Er(Lk)3]3+, where Lk are polyaromatic tridentate ligands, single‐center molecular‐based upconversion using linear optics and exploiting the excited‐state absorption mechanism (ESA) greatly benefits from the design of stable and low‐symmetrical [LkEr(hfa)3] heteroleptic adducts (hfa−=hexafluoroacetylacetonate anion). Depending on (i) the extended π‐electron delocalization, (ii) the flexibility and (iii) the heavy atom effect brought by the bound ligand Lk, the near‐infrared (801 nm) to visible green (542 nm) upconversion quantum yield measured for [LkEr(hfa)3] in solution at room temperature can be boosted by up to three orders of magnitude. [ABSTRACT FROM AUTHOR]

Published

2023

35. ScSmOP: a universal computational pipeline for single-cell single-molecule multiomics data analysis.

Author

Jing, Kai, Xu, Yewen, Yang, Yang, Yin, Pengfei, Ning, Duo, Huang, Guangyu, Deng, Yuqing, Chen, Gengzhan, Li, Guoliang, Tian, Simon Zhongyuan, and Zheng, Meizhen

Subjects

*MULTIOMICS, *DATA analysis, *ELECTRONIC data processing, *DATA mapping, *PIPELINE failures, *CHROMATIN

Abstract

Single-cell multiomics techniques have been widely applied to detect the key signature of cells. These methods have achieved a single-molecule resolution and can even reveal spatial localization. These emerging methods provide insights elucidating the features of genomic, epigenomic and transcriptomic heterogeneity in individual cells. However, they have given rise to new computational challenges in data processing. Here, we describe S ingle- c ell S ingle- m olecule m ultiple O mics P ipeline (ScSmOP), a universal pipeline for barcode-indexed single-cell single-molecule multiomics data analysis. Essentially, the C language is utilized in ScSmOP to set up spaced-seed hash table-based algorithms for barcode identification according to ligation-based barcoding data and synthesis-based barcoding data, followed by data mapping and deconvolution. We demonstrate high reproducibility of data processing between ScSmOP and published pipelines in comprehensive analyses of single-cell omics data (scRNA-seq, scATAC-seq, scARC-seq), single-molecule chromatin interaction data (ChIA-Drop, SPRITE, RD-SPRITE), single-cell single-molecule chromatin interaction data (scSPRITE) and spatial transcriptomic data from various cell types and species. Additionally, ScSmOP shows more rapid performance and is a versatile, efficient, easy-to-use and robust pipeline for single-cell single-molecule multiomics data analysis. [ABSTRACT FROM AUTHOR]

Published

2023

36. Probing Single-molecule Interfacial Electron Transfer Inside a Single Lipid Vesicle.

Author

Das, Atanu Kumar, Mandal, Amit Kumar, and Mondal, Tridib

Subjects

*CHARGE exchange, *ELECTRON donors, *SINGLE molecules, *ORGANIC dyes, *ELECTRON configuration, *LIPIDS

Abstract

Inhomogeneity in single molecule electron transfer at the surface of lipid in a single vesicle has been explored by single molecule spectroscopic technique. In our study we took Di-methyl aniline (DMA), as the electron donor (D) and three different organic dyes as acceptor. These dyes are C153, C480 and C152 and they reside in different regions in the vesicle depending upon their preference of residence. For each probe, we found fluctuations in the single-molecule fluorescence decay, which are attributed to the variation in the reactivity of interfacial electron transfer. We found a non-exponential auto-correlation fluctuation of the intensity of the probe, which is ascribed to the kinetic disorder in the rate of electron transfer. We have also shown the power law distribution of the dark state (off time), which obeys the levy's statistics. We found a shift in lifetime distribution for the probe (C153) from 3.9 ns to 3.5 ns. This observed quenching is due to the dynamic electron transfer. We observed the kinetic disorderness in the electron transfer reaction for each dye. This source of fluctuation in electron transfer rate may be ascribed to the inherent fluctuation, occurring on the time scale of ~ 1.1 ms (for C153) of the vesicle, containing lipids. [ABSTRACT FROM AUTHOR]

Published

2023

37. Spatially mapping the diffusivity of proteins in live cells based on cumulative area analysis.

Author

Gao, Huihui, Han, Chu, and Xiang, Limin

Abstract

Molecular motion provides a way for biomolecules to mix and interact in living systems. Quantifying their motion is critical to the understanding of how biomolecules perform its function. However, it has been a challenged task to spatially map the fast diffusion of unbound proteins in the heterogenous intracellular environment. Here we reported a new imaging technique named cumulative area based on single-molecule diffusivity mapping (CA-SMdM). The strategy is based on the comparison of single-molecule images between a shorter and longer exposure time. With longer exposure time, molecules will travel further, thus giving more blurred single-molecule images, hence implying its local diffusion rates. We validated our technique through measuring the fast diffusion rates (10–40 µm2/s) of fluorescent dye in glycerol-water mixture, and found the values fit well with Stokes-Einstein equation. We further showed that the spatially mapping of diffusivity in live cells is plausible through CA-SMdM, and it faithfully reported the local diffusivity heterogeneity in cytosol and nucleus. CA-SMdM provides an efficient way to mapping the local molecular motion, and therefore will have profound applications in probing the biomolecular interactions for living systems. [ABSTRACT FROM AUTHOR]

Published

2023

38. A Novel Method to Map Small RNAs with High Resolution.

Author

Huang, Kun, Demirci, Feray, Meyers, Blake, and Caplan, Jeffrey

Subjects

DNA-PAINT, In situ hybridization, LNA, Microscopy, RNA detection, Single molecule, Small RNA, Super-resolution, sRNA

Abstract

Analyzing cellular structures and the relative location of molecules is essential for addressing biological questions. Super-resolution microscopy techniques that bypass the light diffraction limit have become increasingly popular to study cellular molecule dynamics in situ. However, the application of super-resolution imaging techniques to detect small RNAs (sRNAs) is limited by the choice of proper fluorophores, autofluorescence of samples, and failure to multiplex. Here, we describe an sRNA-PAINT protocol for the detection of sRNAs at nanometer resolution. The method combines the specificity of locked nucleic acid probes and the low background, precise quantitation, and multiplexable characteristics of DNA Point Accumulation for Imaging in Nanoscale Topography (DNA-PAINT). Using this method, we successfully located sRNA targets that are important for development in maize anthers at sub-20 nm resolution and quantitated their exact copy numbers. Graphic abstract: Multiplexed sRNA-PAINT. Multiple Vetting and Analysis of RNA for In Situ Hybridization (VARNISH) probes with different docking strands (i.e., a, b, …) will be hybridized to samples. The first probe will be imaged with the a* imager. The a* imager will be washed off with buffer C, and then the sample will be imaged with b* imager. The wash and image steps can be repeated sequentially for multiplexing.

Published

2021

39. Three-color single-molecule imaging reveals conformational dynamics of dynein undergoing motility

Author

Niekamp, Stefan, Stuurman, Nico, Zhang, Nan, and Vale, Ronald D

Subjects

Biochemistry and Cell Biology, Biological Sciences, Dyneins, Microtubules, Protein Conformation, Protein Domains, Single Molecule Imaging, dynein&nbsp, motor proteins&nbsp, single molecule&nbsp, fluorescence microscopy, dynein, motor proteins, single molecule

Abstract

The motor protein dynein undergoes coordinated conformational changes of its domains during motility along microtubules. Previous single-molecule studies analyzed the motion of the AAA rings of the dynein homodimer, but not the distal microtubule-binding domains (MTBDs) that step along the track. Here, we simultaneously tracked with nanometer precision two MTBDs and one AAA ring of a single dynein as it underwent hundreds of steps using three-color imaging. We show that the AAA ring and the MTBDs do not always step simultaneously and can take differently sized steps. This variability in the movement between the AAA ring and MTBDs results in an unexpectedly large number of conformational states of dynein during motility. Extracting data on conformational transition biases, we could accurately model dynein stepping in silico. Our results reveal that the flexibility between major dynein domains is critical for dynein motility.

Published

2021

40. Detection of RNA Structure and Interactions Using Nanopore Technology

Author

Byrne, Ashley, Stephenson, William, Barciszewski, Jan, Series Editor, Rajewsky, Nikolaus, Series Editor, and Erdmann, Volker A., Founding Editor

Published

2023

41. Fabricating Solid-State Nanopores for Single-Molecule Sensing

Author

Briggs, Kyle, Waugh, Matthew, Tabard-Cossa, Vincent, Lockwood, David J., Series Editor, and Leburton, Jean-Pierre, editor

Published

2023

42. Fluorescence Microscopy

Author

Mao, Xianwen, Ye, Rong, Chen, Peng, Merkle, Dieter, Managing Editor, Wachs, Israel E., editor, and Bañares, Miguel A., editor

Published

2023

43. Controlled Driving of a Single-Molecule Anthracene-Based Nanocar on a Metal Surface

Author

Barragán, Ana, Lauwaet, Koen, Nicolás-García, Tomás, Sánchez-Grande, Ana, Urgel, José Ignacio, Björk, Jonas, Pérez, Emilio M., Écija, David, Joachim, Christian, Series Editor, Grill, Leonhard, Editorial Board Member, Jelezko, Fedor, Editorial Board Member, Koshino, Masanori, Editorial Board Member, Martrou, David, Editorial Board Member, Nakayama, Tomonobu, Editorial Board Member, Rapenne, Gwénaël, Editorial Board Member, Remacle, Françoise, Editorial Board Member, and Moresco, Francesca, editor

Published

2023

44. From Early Prototypes to On-Surface Drivable Single Molecule Nano-vehicles

Author

Jacquot de Rouville, Henri-Pierre, Adrouche, Sonia, Bouju, Xavier, Launay, Jean-Pierre, Rapenne, Gwénaël, Joachim, Christian, Joachim, Christian, Series Editor, Grill, Leonhard, Editorial Board Member, Jelezko, Fedor, Editorial Board Member, Koshino, Masanori, Editorial Board Member, Martrou, David, Editorial Board Member, Nakayama, Tomonobu, Editorial Board Member, Rapenne, Gwénaël, Editorial Board Member, Remacle, Françoise, Editorial Board Member, and Moresco, Francesca, editor

Published

2023

45. Developing single molecule methods to study DNA replication dynamics in yeasts

Author

Heron, Emma-Louise Darton and Müller, Carolin

Subjects

DNA replication, Genomics, Single molecule

Abstract

To ensure the faithful transmission of genetic information during the cell division cycle, the entire genome must be accurately and completely duplicated prior to segregation of the identical sister chromatids. Perturbation of this process can have severe consequences for a cell, potentially resulting in cell death or genomic instability defects that can contribute to the development of disease. Therefore, it is important to understand how such events are avoided during normal genome replication and the impact of both endogenous and exogenous stresses on the process. For decades, various experimental techniques have been developed and applied to gain insight into the dynamics of genome replication, each contributing to an ever- growing knowledge base on the subject. More recent advances have included the increasing progression towards single cell and single molecule approaches to expand the understanding of cell-to-cell heterogeneity in how replication proceeds. The current work aimed to contribute to these efforts by developing a novel approach for the analysis of single molecule replication dynamics. It was postulated that detecting DNA polymerase usage or lagging strand synthesis by optical mapping in ultra-long single molecules would enable the evaluation of each molecule's pattern of replication. A protocol for mapping Okazaki fragments was established and tested by Bionano Genomics Saphyr analysis. Preliminary results supported the detection of labelled Okazaki fragments, showing potential for further protocol and analytical optimisation to validate this new method. Furthermore, the experimental procedure for the application of an existing single molecule technique in a different model organism was explored. Nanopore sequencing-based detection of nucleotide analogue incorporation during replication was tested in Schizosaccharomyces pombe. Initial analyses indicated that the experimental system was not fully optimised for the approach and required alterations to enable the inference of replication dynamics information from long sequencing reads.

Published

2021

46. Nanopore-mediated protein delivery enabling three-color single-molecule tracking in living cells

Author

Chen, Zhongwen, Cao, Yuhong, Lin, Chun-Wei, Alvarez, Steven, Oh, Dongmyung, Yang, Peidong, and Groves, Jay T

Subjects

Nanotechnology, Bioengineering, Biotechnology, Generic health relevance, Animals, Cell Membrane, Cell Survival, Epidermal Growth Factor, HeLa Cells, Humans, Intracellular Space, Mice, Nanopores, Proteins, Single Molecule Imaging, T-Lymphocytes, EGFR signaling, nanopore, electroporation, single molecule, ex vivo protein delivery, Hela Cells

Abstract

Multicolor single-molecule tracking (SMT) provides a powerful tool to mechanistically probe molecular interactions in living cells. However, because of the limitations in the optical and chemical properties of currently available fluorophores and the multiprotein labeling strategies, intracellular multicolor SMT remains challenging for general research studies. Here, we introduce a practical method employing a nanopore-electroporation (NanoEP) technique to deliver multiple organic dye-labeled proteins into living cells for imaging. It can be easily expanded to three channels in commercial microscopes or be combined with other in situ labeling methods. Utilizing NanoEP, we demonstrate three-color SMT for both cytosolic and membrane proteins. Specifically, we simultaneously monitored single-molecule events downstream of EGFR signaling pathways in living cells. The results provide detailed resolution of the spatial localization and dynamics of Grb2 and SOS recruitment to activated EGFR along with the resultant Ras activation.

Published

2021

47. Neutral lysophosphatidylcholine mediates α-synuclein-induced synaptic vesicle clustering.

Author

Ying Lai, Chunyu Zhao, Zhiqi Tian, Chuchu Wang, Jiaqi Fan, Xiao Hu, Jia Tu, Tihui Li, Leitz, Jeremy, Pfuetzner, Richard A., Zhengtao Liu, Shengnan Zhang, Zhaoming Su, Burré, Jacqueline, Li, Dan, Südhof, Thomas C., Zheng-Jiang Zhu, Cong Liu, Brunger, Axel T., and Jiajie Diao

Subjects

*SYNAPTIC vesicles, *PARKINSON'S disease, *ALPHA-synuclein, *GENETIC disorders, *NEURODEGENERATION

Abstract

α-synuclein (α-Syn) is a presynaptic protein that is involved in Parkinson's and other neurodegenerative diseases and binds to negatively charged phospholipids. Previously, we reported that α-Syn clusters synthetic proteoliposomes that mimic synaptic vesicles. This vesicle-clustering activity depends on a specific interaction of α-Syn with anionic phospholipids. Here, we report that α-Syn surprisingly also interacts with the neutral phospholipid lysophosphatidylcholine (lysoPC). Even in the absence of anionic lipids, lysoPC facilitates α-Syn-induced vesicle clustering but has no effect on Ca2+-triggered fusion in a single vesicle-vesicle fusion assay. The A30P mutant of α-Syn that causes familial Parkinson disease has a reduced affinity to lysoPC and does not induce vesicle clustering. Taken together, the α-Syn-lysoPC interaction may play a role in α-Syn function. [ABSTRACT FROM AUTHOR]

Published

2023

48. DNA curtains to visualize chromatin interactions.

Author

Woodhouse, Mitchell and Brooks Crickard, J.

Subjects

*SINGLE molecules, *DNA, *MOLECULAR evolution, *DNA-protein interactions, *DNA replication

Abstract

• A simple method for fluorescently labeling yeast histones and how to re-fold them into H2A-H2B dimers and H3/H4 tetramers. • A labeling strategy for histone sub-complexes. • A method for real-time visualization of nucleosomes on dsDNA. Recent advances in single molecule imaging have allowed the evolution of biochemical techniques that directly visualize protein-DNA interactions in real-time. These techniques rely on diffraction limited total internal reflection microscopy (TIRFM), and have significantly improved our understanding of RNA transcription, DNA replication, homologous recombination, and general DNA repair in the context of chromatin. Here we described a general single molecule TIRFM technique called DNA curtains to directly visualize how enzymes function on chromatinized DNA. The goal of this manuscript is to introduce the reader to methods to express and reconstitute nucleosomes on long stretches of DNA, and to directly visualize this process using DNA curtains with TIRFM. [ABSTRACT FROM AUTHOR]

Published

2023

49. 1 分子を用いた電子放出位置の光制御.

Author

柳 澤 啓 史

Abstract

In this article, we provide an overview of our recent study on light-induced electron emission from single fullerene molecules and subnanometric optical control of their electron emission sites. After depositing molecules on a sharp metallic needle and applying strong electric fields at the apex of the needle, single-molecule protrusions appear on the apex. The electric fields are further enhanced at the protrusions and the enhanced fields drive electron emissions from the single molecules. Single-molecule electron sources can thereby be created. By irradiating such electron sources with light, we observed large modulations in the electron emission patterns. Our simulations revealed that the emission patterns represent molecular orbitals in a single molecule, a mystery scientists have been trying to get to the bottom of for the past 70 years. Our simulations also explain that light-induced modulation is driven by changes in the molecular orbitals that the emitted electrons pass through. In effect, we realize that there are subnanometric modulations in electron emission sites [ABSTRACT FROM AUTHOR]

Published

2023

50. Biomembrane force probe (BFP): Design, advancements, and recent applications to live-cell mechanobiology.

Author

Moldovan, Laura, Song, Caroline Haoran, Chen, Yiyao Catherine, Wang, Haoqing Jerry, and Ju, Lining Arnold

Subjects

DISPLACEMENT (Mechanics), CARDIOVASCULAR diseases, ERYTHROCYTES

Abstract

Mechanical forces play a vital role in biological processes at molecular and cellular levels, significantly impacting various diseases such as cancer, cardiovascular disease, and COVID-19. Recent advancements in dynamic force spectroscopy (DFS) techniques have enabled the application and measurement of forces and displacements with high resolutions, providing crucial insights into the mechanical pathways underlying these diseases. Among DFS techniques, the biomembrane force probe (BFP) stands out for its ability to measure bond kinetics and cellular mechanosensing with pico-newton and nano-meter resolutions. Here, a comprehensive overview of the classical BFP-DFS setup is presented and key advancements are emphasized, including the development of dual biomembrane force probe (dBFP) and fluorescence biomembrane force probe (fBFP). BFP-DFS allows us to investigate dynamic bond behaviors on living cells and significantly enhances the understanding of specific ligand-receptor axes mediated cell mechanosensing. The contributions of BFP-DFS to the fields of cancer biology, thrombosis, and inflammation are delved into, exploring its potential to elucidate novel therapeutic discoveries. Furthermore, future BFP upgrades aimed at improving output and feasibility are anticipated, emphasizing its growing importance in the field of cell mechanobiology. Although BFP-DFS remains a niche research modality, its impact on the expanding field of cell mechanobiology is immense. [ABSTRACT FROM AUTHOR]

Published

2023